In back-to-back studies published in Nature, researchers from Purdue University and Columbia University report a naturally evolved gene-editing system that can activate genes, offering an advantage over existing CRISPR gene-editing systems that merely find and cut DNA. The research includes two complementary studies, one examining the biological function of the system and the other revealing the molecular mechanism that enables it.

The team’s research on a variant of the CRISPR—Clustered Regularly Interspaced Short Palindromic Repeats—system broadens understanding of CRISPR’s natural diversity and provides a foundation for new gene-regulation technologies. Because this CRISPR variant activates genes without cutting DNA, it could be adapted for precise gene control applications, including research tools and potential therapeutic strategies that turn on genes without permanently altering the genome.

One study shows that this CRISPR system, using a strand of RNA as a guide, finds specific sections of DNA, known as genes, and attracts the cell’s own gene expression machinery to the location to activate the gene. The second study explains how the molecular complex performs this task, revealing how its structure allows it to recruit RNA polymerase—the enzyme responsible for transcribing DNA into RNA—to initiate gene expression.

A research team led by Purdue University’s W. Andy Tao has discovered a new type of protein modification related to cellular mutation that impairs a crucial enzyme’s ability to help drive energy processes. Their discovery, published in Nature Chemistry, opens a new route to therapeutic cancer intervention.

“Mutation is considered the driving mechanism leading to cancer. Many mutations are hidden and harmless, but the mutation of enzymes like kinases can lead to the uncontrolled growth of cancer cells,” said Tao, a professor of biochemistry in Purdue’s College of Agriculture.

The study wades into the interactive dynamic complexity of the human genome (containing 20,000 to 25,000 genes) and the human proteome (containing more than 1 million proteins). The researchers identified a new modification on proteins because of the mutation in the isocitrate dehydrogenase (IDH) enzyme, which affects how kinase enzymes control protein function.

This study analyzed a large cohort of patients with genetic epilepsies using hierarchical clustering analysis to identify homogeneous subgroups defined by specific genetic causes, each showing distinct clinical and EEG patterns.

We included 277 patients (52.3% female; median age at last follow-up 8.1 years, range 0–40). Drug resistance occurred in 58.8% and severe DD/ID in 35.4% of patients. EEG data at onset were available for 107 individuals. Neonatal onset was associated with a higher rate of drug resistance (71.4%; odds ratio [OR] 2.0, 95% CI 1.05–3.77), movement disorders (60.7%; OR 3.7, 95% CI 2.02–6.82), and severe DD/ID (71.4%; OR 7.0, 95% CI 3.66–13.49). Slow EEG background activity and multifocal epileptiform discharges were associated with both drug resistance and severe DD/ID. HCA identified genotype-phenotype groupings, including clusters involving SCN1A, PRRT2, STXBP1, KCNQ2, SCN2A, CHD2, SYNGAP1, and MECP2, each linked to specific clinical and EEG features.